Method for the calibration of an RF integrated circuit probe

Electricity: measuring and testing – Fault detecting in electric circuits and of electric components – Of individual circuit component or element

Reexamination Certificate

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Reexamination Certificate

active

06480013

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Technical Field
The present invention relates to the electrical testing of so-called RF integrated circuits comprising inputs and outputs designed to receive or deliver AC signals in the radio frequency (RF) domain.
The present invention more particularly relates to the electrical testing of RF integrated circuits present on a silicon wafer before the wafer is sliced into individual components.
2. Description of the Related Art
By way of an example,
FIG. 1
shows a silicon wafer
1
on which a large number of integrated circuits
2
having the same structure have-been made by photolithography. The magnified view of
FIG. 2
shows an integrated circuit
2
with an active zone
3
and connection pads
4
electrically connected to the active zone
3
. A greater magnification of the active zone
3
would reveal hundreds or even thousands of integrated circuits together forming various electronic functions that have to be tested.
Since the manufacturing yields for integrated circuits are below 100%, the electrical testing of the integrated circuits
2
that are still on the wafer
1
makes it possible to identify and reject defective integrated circuits or circuits lacking the expected characteristics, before the slicing of the wafer and the mounting of the individualized integrated circuits in a package or on an interconnection medium. This operation is therefore essential for reducing production costs, especially in the context of mass production.
FIG. 3
gives a schematic view of a conventional system for the testing of integrated circuits and wafers, comprising a test station
11
connected to a probe
12
by means of a harness of electrical cables
13
. The probe
12
is a printed circuit card
14
provided with metal tips
15
arranged to coincide. with the connection pads; of an integrated circuit
2
. The wafer
1
is positioned on a tray
16
that is mobile in the horizontal plane and the integrated circuits are tested one after the other by shift motions and rising and descending motions of the tray
16
. The entire system is steered by a test program loaded into a memory
17
that determines the electrical characteristics of the test signal to be applied to the integrated circuits and the measurements to be made.
This conventional procedure for the testing of integrated circuits by means of a probe tip card, which is in widespread use in the industry, is nevertheless limited when it is sought to test RF integrated circuits comprising RF inputs/outputs requiring measurement frequencies ranging from some hundreds of MegaHertz to some GigaHertz. These are special integrated circuits having analog modulation and demodulation functions, mixers, amplifiers, filters, voltage-controlled oscillators (VCOs), phase-locked loops (PLLs), etc. designed for radio receivers, television receivers, mobile radiotelephones, GPS receivers, etc. In this frequency domain, the electrical signals have short wavelengths and various phenomena of reflection and phase rotation appear in the probe
12
and in the conductors
13
connecting the probe to the test station
11
. These phenomena of reflection and rotation distort the electrical measurements by creating interference and changes of electrical level. Furthermore, at high frequency, the copper tracks of the printed circuit card
14
and the probe tips
15
of the probe
12
have non-negligible parasitic capacitance and inductance.
To overcome these drawbacks, specialized firms have developed RF probes offering satisfactory characteristics at high frequency. In particular, the firm Cascade Microtech in Oregon, 97005 USA, proposes RF probe tips (“transmission line probes”) referenced “Air Coplanar” and RFIC membrane probe cards provided with microstrip HF conductors and contact bumps made of nickel. Probes of this kind offer a passband of several tens of Gigahertz, a low reflection coefficient S
11
and a transmission coefficient S
12
with an attenuation of less than 3 dB (see presentation of Cascade™ products on http//www.cmicro.com).
At the same time, the manufacturers of measuring instruments such as the firm Teradyne™ have developed test stations (the A580 series) having RF ports fitted out with an integrated network analyzer or vector network analyzer capable of determining the “IS” parameters (S
11
, S
12
/S
21
and S
22
) of a probe by the OSL (open, short, load) method. As is well known to those skilled in the art, the OSL method consists of the performance of three measurements by the successive application, to the output of the probe, of at least three standard loads, generally an infinite impedance (open circuit), a zero impedance (short circuit) and a 50 ohm impedance (load). On the basis of these three measurements, which are kept in the memory of the instrument, the vector network analyzer determines the “S” parameters of the probe, and the test station, during subsequent measurements, makes an automatic error correction designed to compensate for the influence of these parameters to obtain precise and reliable measurements. At present, the standard loads used are thin-layer circuits on ceramic substrate, calibrated by a national metrology laboratory.
These various means for the electrical testing of RF integrated circuits do not enable the implementation of a satisfactory “on-line” testing method.
Firstly, the Air Copyanar type RF transmission line probes require a manual setting of the orientation of tips and are reserved for laboratory measurements or small production outputs. The membrane probe cards provided with contact bumps, although specially designed for the testing of integrated circuits on wafers, require the use of standard circuits with specific high-cost thin layers in order to be calibrated. For various other practical reasons, the membrane probe cards are not appropriate for the mass production of integrated circuits where the numbers of units manufactured could amount to several millions.
Secondly, at each calibration, the tips or contact bumps of the probes are applied forcefully to the connection pads of the standard circuits, so as to break a surface layer of oxide that forms in contact with air and set up a good electrical contact (“cold welding”). The thin-layer standard circuits, apart from their high cost price, are therefore subject to wear and tear and have short lifetimes.
Finally, the thin-layer standard circuits do not have the same thickness as silicon wafers and, in order to be installed, require an adjustment of the tray
16
(
FIG. 3
) which is necessarily followed by another adjustment of the tray when the wafer is installed. This drawback is in addition to the fact that the RF probes require-several calibration operations during the testing of a batchof chips. These various calibrations imply action by a qualified engineer and take up 5 to 10% of the time devoted to electrical testing.
Thus, a general goal of the present invention is to provide for a method for the calibration of an RF probe that is suited to mass production, and is economical and easy to implement while at the same time being precise and reliable and capable of being implemented, if necessary, by non-skilled staff.
A more particular goal of the present invention is to provide for a standard circuit that has a low cost price and simplifies the calibration of an RF integrated circuit probe.
SUMMARY OF THE INVENTION
These goals are achieved by providing for a method for the calibration of an RF integrated circuit probe comprising a step for the determining, by means of a vector network analyzer and standard circuits, of the characteristics of the RF transmission lines of the probe, wherein the determining step is achieved by means of standard circuits present on a silicon wafer, said standard circuits comprising contact pads corresponding in their layout to RF connection pads of the integrated circuit to be tested and being differentiated from each other by different characteristic impedances measurable from their contact pads.
According to one embodiment, the method comprises a preliminary step f

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